DE102009009698B4 - A method for eye-safe operation of a pulsed noise laser in a DIRCM system - Google Patents

Abstract

Method for the eye-safe operation of a pulsed noise laser (1) in a DIRCM system (10) on board an aircraft, characterized in that
- Echoes of the emitted pulses of the interfering laser (1) are received and evaluated by means of a receiving device (2) and it is determined whether an object (3) is within a predetermined laser safety distance of the DIRCM system (10) in the laser beam,
- The emission of the laser beam is released separately for each time period .DELTA.t within the period of use of the Störlasers, the release for each subsequent period .DELTA.t only occurs if within the respective preceding period .DELTA.t no object was found within the laser safety distance.

Description

The The invention relates to a method for eye-safe operation of a pulsed noise laser in a DIRCM system aboard an air vehicle

Military like Civil aircraft are also becoming increasingly vulnerable to ground-to-air attacks Missiles (LFK) threatened. The most widely used LFK are the so-called MANPADS (Man portable air defense system) with in the infrared spectral range working seeker head.

One possible countermeasure is the emission of directional IR laser radiation modulated by a suitable perturbation sequence against the approaching LFK in order to disturb its seeker head and to move it away from the target. Such systems are referred to as DIRCM systems (Direct Infrared Counter Measures DIRCM) and are z. B. from the DE 4402855A1 or US 6369885B1 known. From the WO2004 / 046750 A2 For example, a DIRCM system is known which uses a search laser which uses a laser beam to detect a threatening missile and additionally a high energy interfering laser to combat the detected missile.

Around To be effective, the interference radiation intensity generated by the DIRCM system must be clear be higher as the infrared radiation of the aircraft to be protected. The usage is too low interference levels Counterproductive, since it facilitates the tracking of the approaching LFK.

to Generation of this interference radiation becomes common a high frequency repetitive pulsed short laser Single pulse durations used.

The required high laser intensities lead to a laser safety problem. The eye safety range of a DIRCM system is, for example according to the European Laser Protection Ordinance EN 60825-1 up to several hundred meters. When operating the DIRCM system It must therefore be ensured that no persons without Stop laser protection within this laser safety distance. this leads to on the authorization and use restrictions of a DIRCM system especially for Situations such as takeoff and landing, in which the potential threat the highest, the Protection by a DIRCM system is thus most important.

Around to ensure compliance with the prescribed laser safety range, are usage restrictions with the help of additional Sensor provided. For example, according to the standard ANSI Z 136.6-2005 Cape. 4.2.7.2 and Chap. 10.5.9 (Laser Institute of America) the laser turned off when the altitude aircraft lower than the NOHD (Nominal Ocular Hazard Distance) or NOHD extended of the laser. The altitude is usually determined in aircraft by a radar altimeter. This method has the disadvantage that below one the NOHD or the NOHD extended corresponding height no protection of the aircraft is given by a DIRCM - straight when the threat is greatest.

at military Applications and approvals are usually the responsibility of the pilot to disable the activation of the laser system when he do not exclude may endanger persons within the laser safety area can. However, this approach is for civil applications and approvals unacceptable. Because many military Airplanes now also civil admitted and used This approach is also of great disadvantage for military aircraft.

From the field of laser rangefinders as well as the laser free field data transmission special methods for securing a non-eye-safe laser beam are known:
In the US 6130754 A The non-eye-safe laser beam is surrounded by an additional eye-safe sheath jet. If objects enter the mantle beam, this is detected by means of the back reflexes and the non-eye-safe beam is switched off. These methods are in principle transferable to a DIRCM system, but have the disadvantage that a second eye-safe laser beam and the corresponding optics for wrapping the non-eye-safe beam and for receiving the back reflections of this cladding jet is required. Overall, a considerable technical effort.

In the US 5837996 A It is checked before release of the non-eye-safe beam on the basis of the back reflection of an eye-safe "test laser" whether no object, and thus no human being, within the laser protection zone. These methods would only be applicable to a DIRCM system if the test laser is outside the spectral range seen by the seeker head of the LFK. Otherwise it would be according to the US 5837996 B1 weaker test lasers are detrimental to the DIRCM application because it supports the seeker in target acquisition. The use of a test laser in another spectral range, however, again requires considerable technical effort.

The invention has for its object to provide a method which allows eye-safe operation of a DIRCM system, without resulting usage restrictions of the DIRCM system, without Schädli effects on its function and with as little equipment as possible.

These The object is achieved with the subject of claim 1. advantageous versions are the subject of dependent claims.

The to be backed DIRCM system due to its appearance and the function required intensities a predetermined laser safety distance of a few hundred Meters (eg NOHD extended according to EN 60825-1) during an operationally required period of use of the Lasers of several seconds. This laser safety distance will in the following "original laser safety distance" of the DIRCM system called.

Of the Störlaser is inventively with a additional Locking device provided, which after a period ☐t prevent the emission of laser radiation. This locking device can over the already present in the DIRCM system modulation device of the laser beam act or independent thereof, e.g. B. be realized as a mechanical beam blocking.

The Time span Δt is measured so that the (eg according to EN 60825-1) from within this time emitted laser energy resulting laser safety distance (hereinafter "reduced Laser safety distance "called) acceptable, low value.

at a DIRCM system, it is not possible, power of the interfering laser radiation because this can lead to significant impairment of function, up to the reversal of the function: Instead of distracting the approaching LFK he is guided to the DIRCM system. Therefore, the fault laser steel even while the period .DELTA.t not eye-safe. Due to the shortness of Δt, however, the (eg according to EN 60825-1) resulting reduced laser safety distance significantly smaller as the original ones Laser safety distance, which essentially consists of the for the DIRCM function required laser usage time of several seconds results.

During the Time span Δt will the backscatter the interfering laser pulses temporally resolved Measured by a receiving device and optionally from the Runtime determines whether the distance of a reflected in the beam of the Störlasers object is less than the original laser safety distance. Unless during this period .DELTA.t no objects within the original laser safety distance be detected, so the emission of the laser radiation is again only for a period Δt released, z. B., in which reset the timer of the locking device becomes. This process will be during the entire duration of use of the DIRCM laser repeated. Will, however an object within the original Laser safety distance during detects one of the consecutive periods Δt, the emission becomes the laser radiation at the end of the relevant period .DELTA.t, within which the object was detected, aborted.

By This procedure ensures that when detecting an object in the laser beam within the original laser safety distance the Laser emission at the latest after a period Δt is prevented. The object is thus only for maximum this period .DELTA.t exposed to the laser irradiation. The entire DIRCM system is thus except for the area within the reduced laser safety distance eye safe. This reduced laser safety distance determined by the time interval Δt can be much lower than the original laser safety distance of the DIRCM system.

The Size of original and Reduced laser safety clearance depends on both the optical Design of the DIRCM system, with the reduced laser safety distance additionally of the length the chosen one Time span Δt depends. In a typical interpretation, z. B. Values of original laser safety distance = 200 m, reduced laser safety distance = 10 m and Δt = 0.1 s.

By the introduction the - for a distance measurement up to a few hundred meters - relative huge Time span Δt is achieved that the possible presence of objects within the primary Laser safety distance in the laser beam with high reliability and negligible Misadaptation rate determined from a plurality of single laser pulses can be. An erroneous response of the locking device is thus avoided.

Of the remaining low protection range within the reduced laser safety distance, as in aircraft z. B. for hedging of weather radars usual, via a "Weight on Wheels "(WOW) Switches are secured. This locks the laser emission as soon as possible the landing gear of the aircraft is loaded, the aircraft so is on the ground. The laser emission is thus only through the WOW switch released in an aircraft in flight. On reason the small size of the reduced Laser safety distance can therefore be safely ruled out that people are in the laser protection area.

A deactivation of the DIRCM system below a minimum height is not required Lich. The DIRCM system equipped according to the invention thus has no usage restrictions due to the laser safety.

The inventive method also leads to that an approaching LFK triggers the blocking of the laser emission, provided he closer as the original laser safety distance to the aircraft. The fight This LFK is thus after the period .DELTA.t, after the LFK the original laser safety distance has fallen short of. As with the resulting short Intervals one fight of the LFK with infrared interference practically is not effective leads however, this does not lead to a relevant functional restriction of the secured according to the invention DIRCM Systems.

There Without response of the locking mechanism no change in the Ausstrahlintensität and the Modulation of the Störlasers is made here are no functional restrictions of the secured according to the invention DIRCM system before.

The Time span Δt can be specified. In an alternative embodiment is the period Δt, while the laser is released, but continuously from the Modulation of the interfering radiation so determined that a fixed value for the reduced laser safety distance within the period Δt is not exceeded. This may vary depending on the actual Modulation (here, in particular, the on / off ratio of the laser of importance) of the Störlasers possibly a higher one Value for the period .DELTA.t used, resulting in an improvement of the false triggering rate the protective mechanism leads.

In In another advantageous embodiment, the original laser safety distance, to which an object detection for triggering the locking mechanism leads, not fixed, but in each case from the past emission period of the Störlaserstrahls determined within the last 10 seconds. According to the EN 60825-1 takes for a DIRCM system the original ones Laser safety distance with the duration of irradiation, with a maximum of one Irradiation of 10 s is. The current original Laser safety distance is thus after z. B. 1 s significantly shorter than z. B. after 5 s laser service life. Thus, it suffices the presence of Objects within the current laser safety distance to check. This leads again to an improvement of the false triggering rate as well as to a smaller usable minimum combat distance.

The invention will be explained in more detail using an exemplary embodiment with reference to a figure. The figure shows a schematic representation of the relevant for carrying out the method according to the invention components of a DIRCM system 10 ,

It includes the pulsed noise laser 1 to combat an approaching LFK. A receiving device 2 receives the backscatter of the emitted laser radiation and evaluates it. In doing so, the distance of the object causing the backscatter becomes 3 measured. The with the interfering laser 1 coupled locking device 4 releases the radiation of the laser energy only for a period of time Δt. A release for the subsequent period takes place only when the receiving device 2 detected within the original laser safety distance during the current period .DELTA.t no object. Otherwise, the emission of the laser radiation is suppressed at the end of the current period .DELTA.t.

The locking device 4 acts according to the embodiment shown in the figure, in which it acts on the modulation means of the laser beam (DIRCM control computer 5 ). Alternatively, the blocking device can also be realized as a mechanical beam blocking.

Claims (5)

Method for eye-safe operation of a pulsed laser ( 1 ) in a DIRCM system ( 10 ) aboard an aircraft, characterized in that - by means of a receiving device ( 2 ) Echoes of the emitted pulses of the interfering laser ( 1 ) are received and evaluated and it is determined whether an object ( 3 ) within a given laser safety distance of the DIRCM system ( 10 ) is in the laser beam, - the emission of the laser beam is released separately for each period .DELTA.t within the period of use of the Störlasers, the release for the respective subsequent period .DELTA.t only occurs if within the respective preceding period .DELTA.t no object was found within the laser safety distance , Method according to claim 1, characterized in that that the time period .DELTA.t continuously from the modulation of the interfering laser beam generated by the DIRCM system is determined. Method according to claim 1, characterized in that that the time period .DELTA.t is fixed. Method according to one of the preceding claims, characterized in that the radiation of the laser is prevented regardless of the presence of an object within the laser safety distance in each case, if the "Weight on Wheels" switch on the aircraft indicates that the aircraft is on the ground. Method according to one of the preceding claims, characterized characterized in that the laser safety distance is continuous from the duration of use of the Störlasers within the last 10 seconds.